Early-Age Cement Paste Temperature Development Monitoring Using Infrared Thermography and Thermo-Sensors

Infrared thermography is an advanced technique usually applied for the assessment of thermal losses through different elements of the building envelope, or as a method for detection of damage (cracks) in reinforced concrete elements, such as bridges. Use of this method for the investigation of tempe...

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Bibliographic Details
Published in:Buildings (Basel) 2023-05, Vol.13 (5), p.1323
Main Authors: Živanović, Nevena, Aškrabić, Marina, Savić, Aleksandar, Stević, Miša, Stević, Zoran
Format: Article
Language:English
Subjects:
Age
Analysis
asymmetric Gaussian
Building envelopes
Cameras
Cement
Cement hydration
cement hydration temperature
Cement paste
Computer software industry
Concrete
Damage detection
Dielectric properties
Electrical installations
Flaw detection
Fly ash
Heat
High temperature
Infrared detectors
Infrared imaging
infrared thermography
Measuring instruments
Methods
Reinforced concrete
Semiconductor industry
Sensors
Slag
supplementary cementitious materials
Temperature measurement
Thermography
Thermometers
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Summary:Infrared thermography is an advanced technique usually applied for the assessment of thermal losses through different elements of the building envelope, or as a method for detection of damage (cracks) in reinforced concrete elements, such as bridges. Use of this method for the investigation of temperature development during early cement hydration is still an evolving area of research. For the purpose of verifying the reliability of the method, two types of cubic samples of different heights were prepared using a cement-based paste, with 20% of cement (by mass) replaced with fly ash. Temperature development was measured in two ways: using infrared thermography and thermo-sensors embedded in the samples. Additionally, the obtained results were modeled using the asymmetric Gaussian function. Peak temperatures in the middle of each sample were higher than the peak temperatures measured on the sample surface, with differences ranging between 2 °C and 4 °C. Differences between the temperature measurements of the thermo-sensors placed on the surface of the sample and thermal camera were lower than 2 °C. Very good compliance of the results was obtained for both the camera and the surface sensors measurements, as well as for the modeling coefficients.
ISSN:2075-5309
2075-5309
DOI:10.3390/buildings13051323